DE2448421C2 - Band-shaped metallic seal for the high-frequency-tight connection of detachable metallic shielding elements - Google Patents

Description

Such a sealing element is known, for example, from the aforementioned CH-PS 5 20460. It exists £ A a contact plate, which is arranged in rows Cross cuts is provided. The four triangular tongues created by a cross cut are squeezed out of the sheet metal surface. There is an angle of 45 ° between the tongues and the sealing plane to prefer. The tongues of adjacent cross cuts point to four different sides Poetry. This creates rows with a large number of tongues, the tongues each in through one Cross cut generated groups of four are arranged. Inside each such group of four occur respectively two tongue pairs, whose projections on the sealing plane are rotated by 180 ° against each other. The cut edges and especially the tips of the triangles dig resiliently into the adjacent ones Surfaces of the shielding elements. An extension of the cross-shaped incisions fills into one Improvement of the spring effect. This is particularly necessary if it is to be ensured that the Seal remains usable for rebuilding after the shielding elements have been installed. But in addition, a resilient support of the tongues causes a constant over long periods of time Damping behavior. This is an essential requirement for shielding elements.

When clamping the seal between the adjacent walls of the shielding elements the resilient tongues protruding from the sealing plane at least partially into the sealing plane pushed back. This tongue movement is called "compression" in the following. In the area of a very small area in the immediate vicinity of the point of intersection of each cross cut then results Contact formation between the four tips of the tongue group and the adjacent shielding element. The next such contact between sealing element and shielding element takes place in the Around the intersection of the next cross cut instead. But since the cross cuts have a certain Can not fall below the minimum length, so that a sufficient spring action of the tongues is guaranteed remains, the individual cross cuts are relatively far apart. This is a relatively low one Contact density between sealing and shielding elements. Therefore occur when current is flowing between the shielding elements via the sealing element, there is considerable sheet resistance in the Seal on. This is not conducive to optimal shielding in the range of low frequencies. This one Disadvantage can at least partially be countered in that the surface of the seal with a highly conductive material is coated. A serious disadvantage occurs at significantly higher frequencies than 1 MHz, since in this area the shielding effect due to gaps in the contact is essential is worsened. The field of application is preferred for the present high-frequency seal in the range of frequencies below about 1 MHz, as is clear from the task. For modern Such a shielding effect is, however, used, for example in the field of electronic computers not broad enough.

There is therefore the task of designing a high-frequency seal of the type mentioned at the outset in such a way that that their damping properties are optimized. This task is solved in that the tongues are individually arranged side by side in such a way that the projections of adjacent tongues of a row rotated against each other by 180 ° on the belt plane are.

This geometrical arrangement enables a very high and even contact density over the whole Sealing surface. The contact formation to the adjacent shielding elements takes place via the tongue tips protruding laterally from the seal, which occur during compression during the pressing process scraping and digging slide on their contact surface. Through the under the tips of the tongue exceptionally high contact pressure, protective layers are penetrated or pierced and a good Conducting electrical contact to the metallic base material of the shielding elements made. When the seal is clamped between the adjacent housing surfaces, the clawing occurs Every tongue tip in the adjacent surfaces acts of force on every single tongue. Components this force lie in the plane of the seal and act perpendicular to its longitudinal edges. By the arrangement of the tongues of a row is avoided, however, that this force effect to a shift of the Spring leads out of its intended position. In the inventive Seal mutually compensate for the thrust forces occurring on the individual tongues and are absorbed by the strength of the sealing material. This avoids that on external displacement forces act on the seal in its entirety. The result during the pressing process The displacement-free position reached by the seal is a prerequisite for the fact that each individual tongues transfer their maximum possible force effect to the support surface and dig in can. This ensures the establishment of reliable contacts. Another advantage of such a seal is that the ratio of the tongue length to the length of the base, i.e. H. the stretch with which the tongue remains in contact with the sealing material, is freely selectable. This relationship affects the through such a resilient tongue achievable spring force. But with this it is possible to exercise the effect of the tongues Force through a suitable shape of the triangular tongues to specified requirements adapt. For example, thicker anti-corrosion layers can be used with a more compact tongue be penetrated with the tip of the tongue.

In an advantageous embodiment, the tips of two tongues of adjacent rows lie on a common perpendicular to the base of the tongues, with the bases of the tongues roughly parallel to the Long edges of the seal lie. This arrangement ensures a low sheet resistance for the Partial flow of current from a tongue of a row to the corresponding tongue of the adjacent row.

Preferably, the projections on the band plane from mutually opposite tongues are adjacent Lines rotated by 180 ° against each other. Occurring for example when clamping the seal Displacement forces between the lines are thereby compensated.

In a preferred embodiment, adjacent ones protrude Pairs of tongues in a row alternate on one or the other side of the seal out. In addition, a pair of tongues protruding to one side of the seal can be in a row a pair of tongues opposite the adjacent row

gene that protrudes from the other side of the seal. This paired arrangement of the tongues protruding on one side becomes a redundant one Contact arrangement achieved. This increases the contact security of the seal. Furthermore this arrangement helps ensure damping behavior that is constant over long periods of time such a seal. Even if a tongue, for example, due to corrosion processes a couple protruding to one side no longer offers electrical contact, at least it remains the contact effect through the second tongue.

In an advantageous shape, the tongues have on their surface facing the seal their entire length has a convex curvature. In a preferred embodiment, the pierces Tangent placed at the tip of the tongue, the sealing plane at an angle between 15 and 30 °. The curvature of the tongues enables a largely fatigue-free contact pressure. curvature and support angle of the tongue tip enable an optimal force effect perpendicular to the spring deflection Support surface without the tongue tip in the starting area of the glide path on its support surface in this is hooked and then permanently deformed. Achieving a high print run pressure Rather, the tip of the tongue slides on the contact surface and, thanks to its special design, is capable of self-phosphating and then varnishing Corrosion protection coatings penetrate. This makes it possible to use a shielding case, for example Electronic cabinets that were not originally intended for high-frequency-tight use, retrospectively retrofit. This means that considerable savings can be achieved.

The seal will preferably consist of a hard, resilient metal. The hardness of the material contributes to the fact that the tongue tips penetrate the protective layers without deformation and with a high Contact pressure with the metallic shielding elements exposed by the scraping process. the The spring action of the material is one of the prerequisites for a fatigue-free shielding effect. Such a seal can be made of V2A steel. This material is characterized by extensive Freedom from corrosion. Such a seal is also used in a corrosive environment retain their effectiveness.

It is economical to form the tongues of a seal by stamping and bending processes. By punching a sharp tear edge occurs on the side of the tongue facing the contact surface of the tip. This favors the penetration of protective layers.

To reduce the sheet resistance for currents that flow between the shielding elements via the Tongue and the seal body flow, the seal can have a highly electrically conductive surface coating be provided.

To increase the ease of assembly, the seal can be on one side with a double-sided adhesive Be provided with foil. This makes the seal non-shifting in its intended position during installation held.

In the following, the invention is illustrated by means of exemplary embodiments in FIGS. 1 to 5 explained. It indicates

F i g. 1 shows a plan view of the sealing tape with

».« .-! iiir,: ^ r ^; r. «r: Hrr -« • "if"'*' * "ΟλΊΚαπ HrAii ^ lrcFnrmi ger tongues,

F i g. 2 shows a section through the in FIG. 1 shown band along the section line 11-11,

F i g. 3 a triangular tongue in an enlarged view,

F i g. 4 shows a section through the individual tongue along the section line VI-VI in FIG. 3 and

F i g. 5, finally, a cross section through a high-frequency-tight connection of a housing profile with ίο a shielding plate.

F i g. 1 shows a plan view of such a high-frequency seal, the metallic sealing strip being designated by 1. Schenküger triangles project from the strip plane up and down out tongues 2 in the form gleichi _S. The tongues are arranged in two lines A and B parallel to the longitudinal edge of the seal. In order to identify the tongues precisely, a lowercase letter is assigned to them in addition to the number 2. The tongues with the reference numerals 2a to 2h belong to line A, the tongues 2m, 2n ... to line β. each tongue is punched out of the seal by a stamping and bending process and bent out of the sealing plane with a suitable curvature. The isosceles triangular recesses formed in the sealing surface after the stamping and bending process are denoted by 20 and the lower case letter of the associated contact tongue.

The individual tongues of a line are punched out of the band-shaped base material of the seal in such a way that the resulting adjacent triangular recesses of a line, for example 20a, 20b from line A or 20m and 20n from line B, are rotated by 180 ° against each other. Due to their arrangement in a row, their tips are not facing each other. The opposite triangular recesses 20c and 20m or 20d and 20n in adjacent rows A and B are arranged so that on a pair with opposite tips 20c; 20m a pair with facing tips 20c /, 2On follows. In Fig. 1, the tips of this pair are each perpendicular to the longitudinal edges of the seal. As a result, the current path between two opposing tongues protruding on different sides of the seal becomes short and the rail resistance is low. Over the length of the tape, a double-sided adhesive film 4 runs parallel to the longitudinal edges as an assembly aid. In this way, before a housing is assembled, the seal is fastened to one of the surfaces that abut one another in the final state. For example, for the high-frequency-tight attachment of a side wall to frame parts of a housing, the wall is provided with such a seal on all surfaces that later rest on frame parts, so that, for example, a rectangular self-contained path is formed from sections of the seal on a rectangular cover wall. When the wall is screwed to the frame, this creates a reliable, high-frequency-tight seal at all joints between the two housing parts.

The section shown in FIG. 2 along the line 11-11 of FIG. 1 shows the bending direction of the individual triangular tongues. A pair of tongues 2c, 2d of row A protrudes downward from the plane spanned by the sealing tape, the left and right adjoining pairs 2a, 2b and 2e, 2 / of row A protrude upward. The pair of tongues 2m opposite the pair of tongues 2c, 2d of row A. 2n of line B protrudes

above out of the sealing plane, the neighboring pair 2o, 2p of row B again downwards. This means that each pair of tongues protruding to one side of the seal, for example 2c, 2d on the left and right in the same line A, is adjoined by two further pairs of tongues la, 2b and 2e, 2 / ″ and opposite in the following line B 2m, 2n , their tips each protrude on the other side of the sealing strip. Because of the paired design of the protruding respectively to one side tongues redundant contact assembly is achieved, which contributes to the increased contact reliability. When installed, then a part current flows from a first shield member for example via the pair of tongues 2c, 2d of the line A in the seal and branches mainly to the adjacent projecting to the opposite side of tip pairs 2a, 2b, 2e. 2 / "row A and 2m, 2n of the line B through which the partial stream flows in the adjacent second shield member. These are the three lowest-resistance parallel current paths. More distant pairs of tongues lead only smaller portions of the partial flow due to the increasing sheet resistance in the seal. These current flow conditions shown using the example of the pair of tongues 2c, 2d apply in an analogous manner to each pair of tongues. It is clear from this that such an arrangement of tongues on a sealing tape produces a reliable, low-resistance contact between adjacent housing parts because of the uniform, high contact density that can be achieved. A prerequisite for the intended effect of such a seal is that the individual pointed tongues have metallic contact with the adjacent housing parts. These housing parts are usually protected against corrosion, ie phosphated and painted. Due to the special choice of material and its shape, the tongues of the high-frequency seal are able to penetrate the corrosion protection layers and thus gain an electrically conductive connection to the metallic base material. F i g. 3 shows a plan view of such a tongue in an enlarged illustration. The triangular tongue 2 is separated from the metallic base material 1 by a punching process and pushed upward out of the sealing plane. With skillful tool design, it is possible to use the punching tool as a bending tool at the same time. This creates a recess in the shape of an isosceles triangle in the plane of the sealing material. A section through the arrangement thus created along the section line IV-IV is shown in FIG. 4. It is of particular importance that the tongue is bent over its entire length from the seal and that the tangent applied to the tip of the tongue penetrates the sealing plane 1 at an angle λ which is between 15 and 30 °. As a result, on the one hand, a sufficiently large spring deflection is given, so that tolerances which occur due to the not completely identical curvature of all such tongues can easily be compensated for. On the other hand, due to the fact that the spring tip does not rest too flat on the adjacent housing surface, considerable forces are exerted perpendicular to the contact surface when it is pressed in. It is of particular importance that the tongue tip slides under high pressure on the adjacent housing surface in a scraping and scoring manner and thereby drills itself into the metallic base material. This is particularly favored by the fact that the punching process produces an extremely sharp-edged tear edge on the side 21 of the tongue 2 facing away from the sealing plane. In order to achieve a sufficiently high elastic contact pressure, the tongue must not be made too narrow at its base 25, ie at the point at which it remains in connection with the base metal of the seal.
When the springs are clamped, the

ίο The tongue tips claw in the support surface when deflecting in the belt plane force components perpendicular to the longitudinal edges of the seal, which are too a displacement of the band-shaped high-frequency seal from its originally intended position being able to lead. By clever arrangement of the individual springs, care is therefore taken that one Force compensation occurs so that no displacement forces are effective on the sealing tape as a whole will. In the in F i g. 1, adjacent tongues act through their arrangement the same line and opposite tongues of different lines together for force compensation, so that the seal as a whole remains free of displacement forces when it is clamped.

In order to keep the sheet resistance for the flow of current in the seal body low, the seal can have a surface coating with a very good electrically conductive metal, for example gold.
F i g. Finally, FIG. 5 shows the high-frequency-tight connection of a housing profile 5 to a shielding plate 6 using a seal according to the invention. The housing profile 5 can, for example, be a vertically extending corner profile of an electronics cabinet. F i g. 5 shows a horizontal section, with the sealing tape 1 perpendicular to the plane of the drawing on the corner profile! runs and is attached to this by a double-sided adhesive tape 4. In order to make the function of the seal easier to understand, a state is shown in which the fastening screw 7 of the shielding plate 6 has not yet been completely screwed into the threaded hole 9 in the corner profile 5. The sharp-edged tips 27 of the tongues 2 resting on the surfaces of the shielding elements 5 and 6 have been pressed closer to the sealing plane against the spring force of the tongues under the action of the contact pressure imparted by the screws 7. The associated horizontal movement of the tips 27 on the bearing surfaces is a prerequisite for penetrating corrosion protection layers on the shielding segments 5 and 6 and for drilling into the metal underneath.

An advantageous material that meets the requirements for hardness on the one hand and resilience on the other, is for example V2A steel. This material also has the advantage that it is extremely Is corrosion-resistant, so that even when installing such housings in rooms with corrosion-promoting Good electrical contacts are guaranteed in the atmosphere.

In summary, it can be stated that the high-frequency seal according to the invention is inexpensive and easy to assemble even with housings not originally intended for high frequency sealing a reliable, broadband seal against high frequency electrical waves can be achieved

509683/322

Claims (13)

Patent claims: 1. Band-shaped metallic seal for the high-frequency-tight connection of detachable metallic shielding elements to be inserted into the parting line of the shielding elements to be connected, with a large number of triangular, resilient tongues, which are arranged in at least one row approximately parallel to the longitudinal edges of the seal and on both sides out of the sealing plane protrude, characterized in that the tongues (2) are individually arranged side by side in such a way that the projections of adjacent tongues (2a, 2b, 2c, 2m, 2n, 2o, 2p) of a line (A, B) on the band plane by 180 ° are twisted against each other. 2. Seal according to claim 1, characterized in that the tips (27) of two tongues (2) of adjacent rows (A, B ) lie on a common perpendicular to their base (25). 3. Seal according to claim 2, characterized in that the base (25) of the tongues (2) is approximately lies parallel to the longitudinal edges of the seal. 4. Seal according to claim 2 or 3, characterized in that the projections on the band plane of mutually opposite tongues of adjacent lines (A, B) are rotated by 180 ° against each other. 5. Seal according to one of claims 1 to 4, characterized in that adjacent pairs of tongues (2a, 2b; 2c, 2 <ή of a line (/ 4J protrude alternately on one or the other side of the seal. 6. Seal according to claim 5, characterized in that that one on one side of the seal (1) protruding pair of tongues (2c 2d) of a line (A) a pair of tongues (2m, 2n) of the adjacent row (B) that protrudes to the other side of the seal 7. Seal according to one of claims 1 to 6, characterized in that the tongues (2) on their the surface (22) facing the seal have a convex curvature over its entire length (Fig.4). 8. Seal according to one of claims 1 to 7, characterized in that the at the tip (27) the tongue (2) applied tangent (8) the sealing plane at an angle between 15 and 30 °. 9. Seal according to one of claims 1 to 8, characterized in that it consists of a hard resilient metal. 10. Seal according to one of claims 1 to 9, characterized in that it is made of V2A steel is 11. Seal according to one of claims 1 to 10, characterized in that the tongues (2) are formed by a stamping and bending process. 12. Seal according to one of claims 1 bu 11, characterized in that it has a surface coating (3) that is a good electrical conductor is provided. 13. Seal according to one of claims 1 to 12, characterized in that the seal is provided on one side with a double-sided adhesive film (4) is. The invention relates to a band-shaped metallic seal for the high-frequency-tight connection of detachable metallic shielding elements for insertion into the joint of the shielding elements to be connected, with a multitude of triangular, resilient tongues, which in at least one of the Longitudinal edges of the seal are arranged approximately parallel line and on both sides out of the sealing plane stick out. Such a high-frequency seal is known from CH-PS 5 20 460, for example In the case of electrical functional units arranged in housings, for example so-called electronic cabinets, it is often necessary to have them Shielding functional groups against electromagnetic vibrations in the outside area or the electromagnetic vibrations emanating from these functional groups affect the interior of the To restrict the housing to disruptive effects on the sensitive in the vicinity of the housing to avoid electronic components. For example, for one in a power plant installed process computer the high-frequency electromagnetic present in the outside space Vibrations are dampened by the computer housing to a level that is harmless to the computer function. A similar problem exists with high frequency generators arranged in housings. Here it is necessary to limit the electromagnetic radiation emerging from the housing to a minimum. Such shielding effects are made possible by metallic housings in the manner of a Faraday Cage work. The framework and walls of such a housing must be in one as possible good electrical contact. While the shielding effect that can be achieved with a normal cabinet is in the order of magnitude of 20 dB, the effect of a welded joint on all sides increases Cabinet to 90 dB. Such a cabinet construction does not make sense because apart from the complex Machining process the easy accessibility, which must be preserved, lost goes. In order to nevertheless provide such housings with the desired damping properties, it is possible to to provide the cabinet parts in contact with a surface that is very good galvanic Contacts guaranteed. However, the cost of such surface finishing is around 60% of the total cabinet costs. Since only a small percentage of the housings used have high requirements must be sufficient with regard to the shielding effect, it does not make much sense for reasons of standardization of the production program all components of such housings at the joints with good galvanic conductivity To provide surfaces. One possible way out lies in the special production of such highly shielding ones Casing. However, any such diversification leads to considerable costs. An inexpensive option for the high-frequency-tight connection of adjacent shielding elements consists in placing specially designed metallic sealing elements in the parting line between the shielding elements, for example between the shielding plates and the frame of a housing, bring in. These sealing elements should be as good as possible when pressed against the joint walls Establish low-level and gap-free contact between the adjacent shielding elements.